Isolator

ABSTRACT

An isolator includes: a working chamber in which work is conducted; an atomizer configured to atomize air or a decontamination material in the working chamber: a pump configured to supply the decontamination material to the atomizer; a compressor configured to supply air to the atomizer; a pressure sensor configured to measure an internal pressure of the working chamber; and a control unit configured to perform a leak test, in which the compressor is driven to supply air from the atomizer into the working chamber thereby pressuring the working chamber, and airtightness of the working chamber is tested based on the internal pressure of the working chamber measured by the pressure sensor.

CROSS-REFERENCE TO RELATED APPLICATION

This is a continuation of application Ser. No. 13/456,303 filed on Apr. 26, 2012, which claims the benefit of priority to Japanese Patent Application No. 2011-102047, filed Apr. 28, 2011, of which full contents are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an isolator.

2. Description of the Related Art

In an isolator used for work of handling a living-organism-derived material, such as cell culture, it is necessary to provide a dust-free/aseptic environment to the highest degree possible (hereinafter, referred to as aseptic environment) inside a working chamber or a pass box for bringing equipment necessary for the work and the like, in order to prevent intrusion of substances other than those necessary for the work.

Hereinafter, a process of killing microorganisms, etc., to realize an aseptic environment is referred to as decontamination, and it is assumed that such a decontamination process includes processes of so-called sterilization, decolonization, and disinfection.

In a sterilizing liquid vaporizing device disclosed in Japanese Laid-Open Patent Publication No.2003-339829, for example, heated compressed air and hydrogen peroxide solution are mixed and atomized by an atomizer, using hydrogen peroxide as decontamination material which is used for decontamination process, thereby producing hydrogen peroxide gas.

As such, decontaminating gas such as the hydrogen peroxide gas containing decontamination material is produced and supplied into a chamber to be decontaminated, such as a working chamber or a pass box, thereby being able to perform a decontamination process.

Each of an inlet and an outlet of the working chamber or the pass box in the isolator are provided with an air filter such as a HEPA (High Efficiency Particulate Air) filter and a ULPA (Ultra Low Penetration Air) filter, in order to remove impurities, such as dust, contained in gas to be taken in and discharged. However, depending on the combination of the decontaminating gas and the air filter to be used, as in a case where the hydrogen peroxide gas is used as the decontaminating gas and the HEPA filter is used as the air filter, for example, the air filter may have a property of having the decontaminating gas adsorbed thereon easily.

Thus, if the decontaminating gas is supplied from the inlet of the working chamber or the pass box, the decontaminating gas is adsorbed by the air filter, which leads to necessity for supplying more than a necessary amount of the decontaminating gas in expectation of an amount thereof to be absorbed, when decontaminating the working chamber or the pass box, resulting in inefficiency. On the other hand, if the decontaminating gas is supplied to the working chamber or the pass box without an air filter, it is not possible to sufficiently decontaminate the air filter (intake filter) of the inlet.

SUMMARY OF THE INVENTION

An isolator according to an aspect of the present invention, includes: a working chamber in which work is conducted; an atomizer configured to atomize air or a decontamination material in the working chamber: a pump configured to supply the decontamination material to the atomizer; a compressor configured to supply air to the atomizer; a pressure sensor configured to measure an internal pressure of the working chamber; and a control unit configured to perform a leak test, in which the compressor is driven to supply air from the atomizer into the working chamber thereby pressuring the working chamber, and airtightness of the working chamber is tested based on the internal pressure of the working chamber measured by the pressure sensor.

Other features of the present invention will become apparent from descriptions of this specification and of the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

For more thorough understanding of the present invention and advantages thereof, the following description should be read in conjunction with the accompanying drawings, in which:

FIG. 1 is a block diagram illustrating a configuration of an isolator according to an embodiment of the present invention;

FIG. 2 is a block diagram illustrating states of valves, blowers, a compressor Cm, and a pump Pm in a leak test mode;

FIG. 3 is a block diagram illustrating states of valves, blowers, a compressor Cm, and a pump Pm in a decontaminating gas production mode;

FIG. 4 is a diagram illustrating control of a valve V3 in a decontaminating gas production mode and a decontaminating gas exposure mode;

FIG. 5 is a block diagram illustrating states of valves, blowers, a compressor Cm, and a pump Pm in a decontaminating gas exposure mode;

FIG. 6 is a block diagram illustrating states of valves, blowers, a compressor Cm, and a pump Pm in a decontaminating gas discharge mode and an aseptic operation mode;

FIG. 7 is a block diagram illustrating another configuration example of an isolator; and

FIG. 8 is a block diagram illustrating state of valves, blowers, a compressor Cm, and a pump Pm in a decontaminating gas production mode in an isolator illustrated in FIG. 7.

DETAILED DESCRIPTION OF THE INVENTION

At least the following details will become apparent from descriptions of this specification and of the accompanying drawings.

Configuration of Isolator

Description will hereinafter be given of a configuration of an isolator according to an embodiment of the present invention with reference to FIG. 1. In an embodiment of the present invention, it is assumed that decontamination effect is achieved by performing the exposure of space to be decontaminated to hydrogen peroxide gas of a predetermined concentration for a predetermined time period, using hydrogen peroxide as an example of a decontamination material which is used in a decontamination process.

In the isolator illustrated in FIG. 1, it is assumed that a working chamber 4 for working in an aseptic environment is the chamber to be decontaminated, and the isolator includes a control unit 1 a, an operating unit 2 a, and a decontaminating gas supply unit 3 a. Further, the working chamber 4 includes an inlet provided with an (intake) filter F1 and an outlet provided with a (discharge) filter F2, and the inlet and outlet are provided with flow paths P1 to P3 that are made of pipes, tubes, or the like. Further, the working chamber 4 includes a pressure sensor 41 configured to measure an internal pressure IP1 of the working chamber 4. The filters F1 and F2 are air filters to remove impurities, such as dust, contained in gas to be taken in and discharged, and a HEPA filter is used, for example.

A (first) flow path P1 is a flow path for taking in outside air to the working chamber 4 through the filter F1, and a catalyst C1, a blower (fan) B1, and a (first) valve V1 are provided on the flow path P1. The blower B1 is a centrifugal multi-blade fan, for example, and is configured to produce an air current to take in the outside air to the working chamber 4 through the flow path P1 in response to a control signal Sb1. Such an air current causes the outside air to flow in through the catalyst C1, to be further supplied into the working chamber 4 through the filter F1. The valve V1 is provided between the blower B1 and the filter F1, and is configured to open/close the flow path P1 in response to a control signal Sv1.

A (second) flow path P2 is a flow path for discharging gas in the working chamber 4 through the filter F2, and a blower B2, a catalyst C2, and a (second) valve V2 are provided on the flow path P2. The blower B2 is a centrifugal multi-blade fan, for example, and is configured to produce an air current to discharge the gas in the working chamber 4 through the flow path P2 in response to a control signal Sb2. Such an air current causes the gas in the working chamber 4 to flow out through the filter F2, and the hydrogen peroxide (decontamination material), upon being decomposed/rendered harmless by the catalyst C2, to be discharged to the exterior. In an embodiment of the present invention, the catalyst C2 corresponds to a detoxifying unit configured to reduce the amount of the decontamination material to be rendered harmless (detoxified). The valve V2 is provided between the catalyst C2 and the filter F2, and is configured to open/close the flow path P2 in response to a control signal Sv2.

A (third) flow path P3 is a flow path for discharging the gas in the working chamber 4 through the filter F1 in a decontaminating gas production mode and a decontaminating gas exposure mode which will be described later, and generally, the volume of the gas flowing therethrough is smaller than that flowing through each of the flow paths P1 and P2. One end of the flow path P3 is connected between the catalyst C2 and the valve V2 in the flow path P2 while the other end thereof is connected to the filter F1, and a (third) valve V3 is provided on the flow path P3. The valve V3 is configured to open/close the flow path P3 in response to a control signal Sv3.

The decontaminating gas supply unit 3 a includes a tank 31, a bottle 32, a water level sensor 33, an atomizer 34, and a filter F32, and further includes flow paths P31 to P33, made of pipes, tubes, or the like, which are provided to connect the above components.

A flow path P31 connects between the tank 31 and the bottle 32, and a pump Pm and a filter F31 are provided on the flow path P31. For example, a peristaltic pump is used as the pump Pm so as to deliver fluid in a state dust-free and aseptic as possible, and hydrogen peroxide solution (decontamination material solution) stored in the tank 31 is taken in, in response to a control signal Spm. Then, the hydrogen peroxide solution taken in as such is delivered toward the atomizer 34 side through the filter F31 for removing impurities, such as dust.

The bottle 32 is opened to the outside air through the (air) filter F32, and acts as a buffer for collecting the hydrogen peroxide solution that has not been injected as hydrogen peroxide gas (decontaminating gas) from the nozzle of the atomizer 34. The bottle 32 is provided with a water level sensor 33 configured to measure water level WL1 of the collected hydrogen peroxide solution.

One end of the flow path P32 is connected between the filter F31 and the bottle 32 in the flow path P31 while the other end thereof is connected to a lower port of the atomizer 34, and a valve V31 is provided on the flow path P32. The valve V31 is configured to open/close the flow path P32 in response to a control signal Sv31.

A flow path P33 is a flow path for supplying compressed air (compressed gas) to the atomizer 34, and a compressor Cm, a filter F33, and a valve V32 are provided on the flow path P33. The compressor Cm is configured to take in the outside air and compress it in response to a control signal Scm, and such compressed air is supplied to an upper port of the atomizer 34 through the (air) filter F33 for removing impurities, such as dust and moisture content. The valve V32 is provided between the filter F33 and the upper port of the atomizer 34 and is configured to open/close the flow path P33 in response to a control signal Sv32.

A mode selection signal SLm is inputted to the control unit 1 a from the operating unit 2 a, and the control unit 1 a is configured to switch the operation mode, which will be described later, in response to the mode selection signal SLm. Further, control unit 1 a is configured to output, in addition to switching the operation mode, the control signals Sv1 to Sv3, Sv31, Sv32, Sb1, Sb2, Scm, and Spm for controlling the valves, blowers, the compressor Cm, and the pump Pm based on the internal pressure IP1 and the water level WL1.

Operation of Isolator

A description will hereinafter be given of an operation of the isolator according to an embodiment of the present invention with reference to FIGS. 2 to 6, as appropriate.

The operation mode of the isolator according to an embodiment of the present invention is switched in response to the mode selection signal SLm, and such mode can be broadly classified into: a decontaminating operation mode (SLm=1 to 4) for decontaminating the working chamber 4 (chamber to be decontaminated); and an aseptic operation mode (SLm=5) for working in the working chamber 4 where the aseptic environment has been provided by decontamination being performed. The decontaminating operation mode includes a leak test mode (SLm=1) the decontaminating gas production mode (SLm=2), the decontaminating gas exposure mode (SLm=3), and a decontaminating gas discharge mode (SLm=4).

In the decontaminating operation mode, firstly, airtightness of the working chamber 4 is tested in the leak test mode. In the leak test mode, as illustrated in FIG. 2, the control unit 1 a drives the compressor Cm as well as opens the valve V32 in a state where the blowers B1 and B2 and the pump Pm are stopped with the valves V1 to V3 and V31 closed. Then, by such control, the atomizer 34 of the decontaminating gas supply unit 3 a supplies, from a nozzle thereof, only the compressed air supplied to the upper port thereof into the working chamber 4, thereby pressurizing the working chamber 4.

In such pressurized state of the working chamber 4, the control unit 1 a determines the airtightness of the working chamber 4 based on the internal pressure IP1 of the working chamber 4 measured by the pressure sensor 41. For example, the control unit 1 a determines that the airtightness of the working chamber 4 is in a good condition, when an amount of decrease in the internal pressure IP1 after elapse of a predetermined time equals a pressure that is equal to or lower than a predetermined pressure.

When it is determined that the airtightness of the working chamber 4 is in a good condition in the leak test mode, next, the hydrogen peroxide gas is supplied into the working chamber in the decontaminating gas production mode. The decontaminating gas production mode is commenced when the control unit 1 a drives the pump Pm and opens the valve V31 in the state of the leak test mode and further controls opening/closing of the valve V3, as illustrated in FIG. 3.

By such control, the compressed air is supplied to the upper port of the atomizer 34, as in the leak test mode. Negative pressure is produced by injecting the compressed air from the nozzle of the atomizer 34, and such negative pressure causes the hydrogen peroxide solution, delivered by the pump Pm from the tank 31 toward the atomizer 34, to be supplied to the lower port of the atomizer 34. Then, the compressed air and the hydrogen peroxide solution are mixed in the atomizer 34, to be injected as atomized hydrogen peroxide solution, thereafter immediately vaporized, and supplied as the hydrogen peroxide gas.

As such, in the isolator according to an embodiment of the present invention, the hydrogen peroxide gas is directly supplied into the working chamber 4 without flowing through the filters F1 and F2, in the decontaminating gas production mode. Thus, the hydrogen peroxide gas is supplied into the working chamber 4 without loss by absorption into the filters F1 and F2, thereby being able to perform a process of decontaminating the inside of the working chamber 4 in an efficient manner.

The decontaminating gas supply unit 3 a can produce hydrogen peroxide gas utilizing the negative pressure produced by injection of compressed air, without heating or using ultrasonic waves . If some kind of failure should stop the supply of the compressed air to the atomizer 34, the hydrogen peroxide solution delivered by the pump Pm is collected in the bottle 32 utilizing the difference in flow-path resistance caused by the difference in flow-path diameter, avoiding supply into the working chamber 4 in a liquid state. Then, the control unit 1 a stops the pump Pm to stop delivering the hydrogen peroxide solution when the water level WL1 of the hydrogen peroxide solution measured by the water level sensor 33 reaches a water level that is equal to or greater than a predetermined level.

In the decontaminating gas production mode, the control unit 1 a further controls opening/closing of the valve V3 based on the internal pressure IP1 of the working chamber 4. For example, as illustrated in FIG. 4, if the internal pressure IP1 exceeds a predetermined positive pressure IPtg, the valve V3 is opened; while if the internal pressure IP1 equals or falls below the predetermined positive pressure IPtg, the valve V3 is closed. Then, when the valve V3 is opened, the hydrogen peroxide gas in the working chamber 4 is discharged through the filter F1. The permissible flow rate through the valve V3 is lower than that through each of the valves V1 and V2, which leads the valve V3 to have greater responsiveness, thereby being able to accurately control the internal pressure IP1 with the control unit 1 a.

As such, in the isolator according to an embodiment of the present invention, in the decontaminating gas production mode, the hydrogen peroxide gas in the working chamber 4 is discharged through the filter F1 while the internal pressure IP1 of the working chamber 4 is adjusted to the predetermined positive pressure IPtg. Thus, the filter F1, which is an intake filter, can be sufficiently decontaminated.

After the hydrogen peroxide gas is supplied into the working chamber 4 in the decontaminating gas production mode, the interior of the working chamber 4 is exposed to hydrogen peroxide gas in the decontaminating gas exposure mode. In the decontaminating gas exposure mode, after proceeding from the state of the decontaminating gas production mode, the control unit 1 a stops the pump Pm as well as closes the valve V31, as illustrated in FIG. 5. Then, by such control, the decontaminating gas supply unit 3 a supplies, from the nozzle, only the compressed air into the working chamber 4 as in the leak test mode, and further, the control unit 1 a controls opening/closing of the valve V3 based on the internal pressure IP1 of the working chamber 4 as in the decontaminating gas production mode.

As such, in the isolator according to an embodiment of the present invention, in the decontaminating gas exposure mode, the interior of the working chamber 4 is exposed to the hydrogen peroxide gas, which is supplied in the decontaminating gas production mode. Further, in the decontaminating gas exposure mode as well, the hydrogen peroxide gas in the working chamber 4 is discharged through the filter F1 while the internal pressure IP1 of the working chamber 4 is adjusted to the predetermined positive pressure IPtg. Thus, by proceeding from the decontaminating gas production mode to the decontaminating gas exposure mode, the interior of the working chamber 4 and the filter F1 can be sufficiently decontaminated while suppressing the consumption of the hydrogen peroxide solution stored in the tank 31.

After the interior of the working chamber 4 is sufficiently exposed to the hydrogen peroxide gas in the decontaminating gas exposure mode, the hydrogen peroxide gas in the working chamber 4 is discharged in the decontaminating gas discharge mode. In the decontaminating gas discharge mode, after proceeding from the state of the decontaminating gas exposure mode, the control unit 1 a drives the blowers B1 and B2 as well as opens the valves V1 and V2 and closes the valve V3; and stops the compressor Cm as well as closes the valve V32, as illustrated in FIG. 6.

By such control, the decontaminating gas supply unit 3 a stops supplying the compressed air and the hydrogen peroxide gas into the working chamber 4. Further, the control unit 1 a controls the number of revolutions of the blowers B1 and B2 based on the internal pressure IP1 of the working chamber 4, and adjusts the internal pressure IP1 of the working chamber 4 to the predetermined positive pressure IPtg, as in the decontaminating gas production mode and the decontaminating gas exposure mode. Thus, the outside air is taken into the working chamber 4 through the flow path P1, and the hydrogen peroxide gas in the working chamber 4 is discharged through the flow path P2. Then, through continuous operation of such for predetermined time period, the hydrogen peroxide gas in the working chamber 4 is replaced by outside fresh air.

In the isolator according to an embodiment of the present invention, the filter F2, being a discharge filter, is decontaminated in the decontaminating gas discharge mode. Further, after the hydrogen peroxide gas in the working chamber is sufficiently discharged in the decontaminating gas discharge mode, the mode proceeds to the aseptic operation mode, and control therein is similar to that in the decontaminating gas discharge mode.

Another Configuration Example of Isolator

In an embodiment described above, it was assumed that only the working chamber 4 is the chamber to be decontaminated, however, it is not limited thereto. For example, as illustrated in FIG. 7, a pass box 5 for bringing equipment necessary for the work into the working chamber 4 through a door 52 may be the chamber to be decontaminated, in addition to the working chamber 4. It should be noted that the components for decontaminating the working chamber 4 are similar to those in the isolator according to an embodiment described above, and thus are omitted in FIG. 7 except for the atomizer 34 and the like. Description of the components for decontaminating the working chamber 4, which are common to those in an embodiment described above, will hereinafter be omitted.

The isolator illustrated in FIG. 7 includes a control unit 1 b, an operating unit 2 b, and a decontaminating gas supply unit 3 b. The pass box 5 includes an inlet provided with an (intake) filter F3 and an outlet provided with a (discharge) filter F4, and the inlet and outlet are provided with flow paths P4 to P6. Further, the pass box 5 includes therein a pressure sensor 51 configured to measure the internal pressure IP2 of the pass box 5.

A (first) flow path P4 is a flow path for taking in the outside air to the pass box 5 through the filter F3, and a catalyst C3, a (first)valve V4, and a blower B3 are provided on the flow path P4. Whereas, a (second) flow path P5 is a flow path for discharging gas in the pass box 5 through the filter F4, and a catalyst C4 and a (second) valve V5 are provided on a flow path P5. The blower B3 is an axial-flow fan, for example, and is configured to produce air currents to take in the outside air to the pass box 5 through the flow path P4 as well as discharge the gas in the pass box 5 through the flow path P5, in response to a control signal Sb3. Since the capacity of the pass box 5 is smaller than that of the working chamber 4, such intake and discharge are performed by the a single blower B3.

By the air currents, the outside air flows in through the catalyst C3, and is further supplied into the pass box 5 through the filter F3, while the gas in the pass box 5 flows out through the filter F4, and furthermore the hydrogen peroxide is decomposed/rendered harmless by the catalyst C4, to be discharged to the exterior. The valve V4 is provided between the catalyst C3 and the blower B3, and is configured to open/close the flow path P4 in response to a control signal Sv4; while the valve V5 is provided between the catalyst C4 and the filter F4, and is configured to open/close the flow path P5 in response to a control signal Sv5.

A (third) flow path P6 is a flow path for discharging the gas in the pass box 5 through the filter F3 in the decontaminating gas production mode and the decontaminating gas exposure mode. One end of the flow path P6 is connected between the catalyst C4 and the valve V5 in the flow path P5 while the other end thereof is connected to the filter F3, and a (third) valve V6 is provided on the flow path P6. The valve V6 is configured to open/close the flow path P6 in response to a control signal Sv6.

The decontaminating gas supply unit 3 b includes the tank 31, the bottles 32 and 35, the water level sensors 33 and 36, the atomizers 34 and 37, and the filters F32 and F34, and further includes the flow paths P31 to P33 and flow paths P34 to P36 provided so as to connect the aforementioned components.

The flow path P31 connects between the tank 31 and the bottles 32 and 35; and the pump Pm, the filter F31, and a valve V35 are provided on the flow path P31. Further, the pump Pm is configured to take in the hydrogen peroxide solution stored in the tank 31 and deliver it toward the atomizers 34 and 37 through the filter F31, in response to the control signal Spm. Further, the valve V35 allows the hydrogen peroxide solution filtered by the filter F31 to pass therethrough toward the atomizer 34 or the atomizer 37 in response to a control signal Sv35.

The bottle 32 is opened to the outside air through the (air) filter F32, and the bottle 32 is provided with the water level sensor 33 configured to measure the water level WL1 of the hydrogen peroxide solution. Whereas, the bottle 35 is opened to the outside air through the (air) filter F34, and the bottle 35 is provided with the water level sensor 36 configured to measure a water level WL2 of the hydrogen peroxide solution.

One end of the flow path P32 is connected to the flow path P31 between the valve V35 and the bottle 32 while the other end thereof is connected to the lower port of the atomizer 34, and the valve V31 is provided on the flow path P32. Whereas, one end of a flow path P34 is connected to the flow path P31 between the valve V35 and the bottle 35 while the other end thereof is connected to a lower port of the atomizer 37, and a valve V33 is provided on the flow path P34. The valve V31 is configured to open/close the flow path P32 in response to the control signal Sv31, and the valve V33 is configured to open/close the flow path P34 in response to a control signal Sv33.

The flow path P33 is a flow path for supplying compressed air to the atomizer 34 or 37, and is bifurcated into the flow path P35 connected to the atomizer 34 and a flow path P36 connected to the atomizer 37. The compressor Cm and the filter F33 are provided on the flow path P33, the valves V32 and V34 are provided on the flow paths P35 and P36, respectively.

Further, the compressor Cm is configured to take in the outside air to be compressed in response to the control signal Scm, and such compressed air is supplied to the upper port of the atomizer 34 or the atomizer 37 through the (air) filter F33. The valve V32 is provided between the filter F33 and the upper port of the atomizer 34 and is configured to open/close the flow path P35 in response to the control signal Sv32, while the valve V34 is provided between the filter F33 and the upper port of the atomizer 37 and is configured to open/close the flow path P36 in response to a control signal Sv34.

From the operating unit 2 b, a decontamination-target-chamber-selection signal SLr and the mode selection signal SLm are inputted to the control unit 1 b. The control unit 1 b is configured to select the working chamber 4 or the pass box 5 as the chamber to be decontaminated in response to the decontamination-target-chamber-selection signal SLr, and switch an operation mode in response to the mode selection signal SLm. Further, the control unit 1 b is configured to output, in addition to selecting the chamber to be decontaminated and switching the operation mode, the control signals Sv1 to Sv6, Sv31 to Sv35, Sb1 to Sb3, Scm, and Spm based on the internal pressures IP1 and IP2 and the water levels WL1 and WL2. The decontaminating gas supply unit 3 b is configured to supply the compressed air and the hydrogen peroxide gas into the chamber to be decontaminated selected in response to the decontamination-target-chamber-selection signal SLr.

In the isolator illustrated in FIG. 7, the operation mode is switched in response to the mode selection signal SLm, and the control is performed as in the isolator according to an embodiment described above. For example, in the decontaminating gas production mode with respect to the pass box 5, as illustrated in FIG. 8, the decontaminating gas supply unit 3 b has the compressed air supplied to the upper port of the atomizer 37 and the hydrogen peroxide solution supplied to the lower port thereof by the negative pressure, to directly supply the hydrogen peroxide gas into the pass box 5. Further, the control unit 1 b is configured to control opening/closing of the valve V6 based on the internal pressure IP2 of the pass box 5, so as to discharge the hydrogen peroxide gas in the pass box 5 thorough the filter F3 while the internal pressure IP2 of the pass box 5 is adjusted to the predetermined positive pressure IPtg.

As described above, in the decontaminating gas production mode illustrated in FIG. 1 (FIG. 7), the hydrogen peroxide gas, which is the decontaminating gas, is directly supplied into the working chamber 4 (pass box 5), which is the chamber to be decontaminated, without flowing through the filters F1 (F3), F2 (F4), which is the intake filter and the discharge filter, respectively, and the decontaminating gas in the chamber to be decontaminated is discharged through the intake filter, thereby being able to supply a sufficient amount of decontaminating gas into the chamber to be decontaminated, and further being able to sufficiently contaminate the intake filter. Thus, the process of decontaminating the chamber to be decontaminated and the intake filter can be improved in efficiency.

Further, in the decontaminating gas production mode, while the decontaminating gas is being supplied from the decontaminating gas supply unit 3 a (3 b) into the chamber to be decontaminated, the third flow path P3 (P6), which is opened/closed by the third valve V3 (V6), is opened in the state where the blowers B1 and B2 (blower B3) are (is) stopped as well as the first flow path P1 (P4) for performing intake and the second flow path P2 (P5) for performing discharge using the blowers (blower) are closed, so that the decontaminating gas in the chamber to be decontaminated is discharged through the intake filter and the third flow path, thereby being able to sufficiently decontaminate the intake filter.

Further, the catalyst C2 (C4) for decomposing the decontamination material is provided on the side more distant (away) from the discharge filter as compared with the second valve V2 (V5) configured to open/close the second flow path, and one end of the third flow path is connected between the catalyst and the second valve, and the other end thereof is connected to the intake filter, thereby, after decomposing and rendering harmless the decontamination material contained in the decontaminating gas, is allowed to discharge to the exterior, which is discharged not only in the decontaminating gas discharge mode and the aseptic operation mode but also the decontaminating gas production mode and the decontaminating gas exposure mode.

Further, in the decontaminating gas production mode, opening/closing of the third valve is controlled based on the internal pressure IP1 (IP2) of the chamber to be decontaminated that is measured by the pressure sensor 41 (51), thereby being able to discharge the decontaminating gas in the chamber to be decontaminated through the intake filter, while the internal pressure of the chamber to be decontaminated is adjusted to the predetermined positive pressure IPtg.

Further, in the decontaminating gas production mode, the compressed air and the decontamination material are mixed to produce the decontaminating gas, to be supplied into the chamber to be decontaminated, and thereafter, in the decontaminating gas exposure mode, while only the compressed air is being supplied into the chamber to be decontaminated, opening/closing of the third valve is controlled as in the decontaminating gas production mode, thereby being able to sufficiently decontaminate the interior of the chamber to be decontaminated and the intake filter while suppressing the consumption of the decontamination material.

Further, only the compressed air is supplied into the chamber to be decontaminated in the state where all the first to third flow paths are closed, thereby being able to test the airtightness of the chamber to be decontaminated based on the internal pressure of the chamber to be decontaminated.

The above embodiments of the present invention are simply for facilitating the understanding of the present invention and are not in any way to be construed as limiting the present invention. The present invention may variously be changed or altered without departing from its spirit and encompass equivalents thereof. 

What is claimed is:
 1. An isolator comprising: a working chamber in which work is conducted; an atomizer configured to atomize air or a decontamination material in the working chamber: a pump configured to supply the decontamination material to the atomizer; a compressor configured to supply air to the atomizer; a pressure sensor configured to measure an internal pressure of the working chamber; and a control unit configured to perform a leak test, in which the compressor is driven to supply air from the atomizer into the working chamber thereby pressuring the working chamber and airtightness of the working chamber is tested based on the internal pressure of the working chamber measured by the pressure sensor.
 2. The isolator according to claim 1, further comprising: a first valve provided between the atomizer and the pump, wherein the control unit configured to close the first valve and then conduct the leak test.
 3. The isolator according to claim 2, wherein the control unit is configured to, after conducting the leak test, drive the pump and open the first valve, thereby mixing the air and the decontamination material in the atomizer, to be injected into the working chamber.
 4. The isolator according to claim 1, further comprising: a second valve provided between the atomizer and the compressor, wherein the control unit is configured to open the second valve and then conduct the leak test.
 5. The isolator according to claim 2, further comprising: a second valve provided between the atomizer and the compressor, wherein the control unit is configured to open the second valve and then conduct the leak test.
 6. The isolator according to claim 3, further comprising: a second valve provided between the atomizer and the compressor, wherein the control unit is configured to open the second valve and then conduct the leak test.
 7. The isolator according to claim 1, further comprising: a filter provided between the atomizer and the compressor.
 8. The isolator according to claim 2, further comprising: a filter provided between the atomizer and the compressor.
 9. The isolator according to claim 3, further comprising: a filter provided between the atomizer and the compressor.
 10. The isolator according to claim 4, further comprising: a filter provided between the atomizer and the compressor.
 11. The isolator according to claim 5, further comprising: a filter provided between the atomizer and the compressor.
 12. The isolator according to claim 6, further comprising: a filter provided between the atomizer and the compressor.
 13. A method for controlling an isolator, comprising: a first step of pressuring a working chamber by driving a compressor to supply air from an atomizer into the working chamber; and a second step of measuring an internal pressure of the pressurized working chamber with a pressure sensor and testing airtightness of the working chamber.
 14. A method for controlling an isolator according to claim 13, further comprising: a third step of driving the compressor to supply air to the atomizer and driving a pump to supply a decontamination material to the atomizer, and mixing the air and the decontamination material in the atomizer, to be injected into the working chamber. 